FAN TERMINAL UNITS Constant Volume (Series Flow), Standard Design

FAN TERMINAL UNITS Constant Volume (Series Flow), Standard Design Fan motor (PSC or ECM). UL Listed 1 insulation conforms to UL Test 181 and NFPA 90A. Plenum air filter rack. (Filter Optional) Casing has removable bottom access panel for servicing internal parts. Sturdy 22 gauge galvanized steel construction. Damper/fan control enclosure. (Standard) Calibration chart for flow measuring and balancing. 3/8 damper shaft rotates in three oil impregnated sintered bronze bearings. Slot in damper shaft to indicate damper position. Thermally insulated inlet collar. Tri-Averaging inlet sensor amplifies velocity pressure signals for air flow measuring and pressure independent flow control. Electronic damper controls shown. (Pneumatic Available) Integral air flow switch. (Included with Carnes Controls Only) Transformer (Optional) Fan contactor. (Standard) SCR fan speed control. (Standard) Toggle disconnect. (Optional) OPTIONAL ETL LISTING INSIDE CONTROLS ENCLOSURE B-88 www.carnes.com

UNIT SELECTION PROCEDURE Fan Powered Terminal Units CONSTANT VOLUME FAN TERMINALS From the job specification or schedule, determine the Maximum and Minimum primary CFM requirement for each zone. Refer to the fan curves located under the Performance Data Section of this catalog. Select a Fan Size from these curves, making sure that the fan selected can deliver the Maximum Primary CFM at a given downstream external static pressure [ESP]. Downstream ESP consists of ductwork, flex, coils etc. NOTE: For proper operation, it is recommended that the downstream ESP be at least 0.20 WG. Units must be selected to operate within the minimum and maximum range of the fan curves. Fan speed controllers [SCR] are provided as standard to allow air flow adjustments and balancing. Inlet size is predetermined according to the Fan Size selected for constant volume units. See Quick Selection Table. After a Fan Size is selected, refer to the Primary Air Inlet Parameter chart Table. Make sure that the Minimum primary CFM is within the ranges shown for Pneumatic or Electronic controls. Sound Level: Refer to the sound section of this catalog to determine if the unit selected meets the required NC or Db levels specified. Pressure Drop: Refer to the performance section of this catalog to determine the air differential pressure [DPs]. DPs is the static pressure difference from the inlet to discharge and does not include hot water or electric coils. See coil selection for Ps of these devices. Heating Coils: For units that require hot water or electric heat refer to the appropriate sections of this catalog for performance data. Controls: See Control Section for Terminal Unit Controls and the sequence of operation as specified. INTERMITTENT VOLUME FAN TERMINALS From the job specification or schedule, determine the Maximum and Minimum primary CFM requirement for each zone. Select a unit size within the Maximum and Minimum primary CFM range. Maximum CFM should not exceed the maximum rating shown. [Maximum rating based on approximately 3000 FPM]. Minimum CFM should be selected within the pneumatic or electronic minimum CFM ranges shown. [A minimum of 0 CFM is also acceptable if specified]. Evaluate the fan CFM requirement for each unit and refer to the Fan Curves of this catalog. Note: Actual heating CFM = fan CFM + minimum primary CFM. Select a Fan Size from these curves, making sure that the fan selected can deliver the desired CFM at a given downstream external static pressure [ESP]. Downstream ESP consists of ductwork, flex, coils, etc. Note: For proper operation, it is recommended that the downstream ESP be at least 0.20 WG. Units must be selected to operate within the minimum and maximum range of the fan curves. Fan speed controllers [SCR] are provided as standard to allow air flow adjustments and balancing. After the Fan and Inlet Size is determined refer to the Quick Selection Table to make sure that your selection is available. You will notice that there are many Fan and Inlet size combinations shown for intermittent fan terminals [AS units]. Sound Level: Refer to the sound section of this catalog to determine if the unit selected meets the required NC or db levels specified. Pressure Drop: Refer to the performance section of this catalog to determine the air differential pressure [DPs]. DPs is the static pressure difference from the inlet to discharge and does not include hot water or electric coils. See coil selection for DPs of these devices. Heating Coils: For units that require hot water or electric heat refer to the appropriate sections of this catalog for performance data. Note: Actual heating CFM = fan CFM + minimum primary CFM. Controls: See Control Section for Terminal Unit Controls and the sequence of operation as specified. Typical Sequence of Operation Intermittent Volume Central fan on Day (occupied) operation. When the central system fan is on, the intermittent fan unit operates as a standard throttling control unit for cooling loads. As the cooling load diminishes the control valve throttles to a minimum or closed position, the fan is energized by the P/E switch for pneumatic controls or an electric contactor for electronic controls to draw in warm plenum air. Thermostat is calling for heat. Central fan on Day (occupied) operation. When the central system fan is on and a positive pressure of at least.10 IWC is present at the primary air inlet, the unit air flow switch senses this pressure and keeps the fan on all the time by overriding the unit P/E switch action with pneumatic controls or electric contactor with electronic controls. Central fan off Night (unoccupied) operation. When the central system fan is off, on a call for less cooling, the primary air supply valve closes. The unit fan is then turned on and off by the P/E switch for pneumatic controls or an electric contactor for electronic controls on demands for heat and not heat respectively. CAUTION: For electronically controlled unit, a minimum CFM value other than zero may cause the damper to drive open when the central system is off. Typical Sequence of Operation Constant Volume Central fan off Night (unoccupied) operation. When the central system fan is off at 0.0 to negative pressure is present at the primary air inlet. The air flow switch senses the negative pressure and is taken out of the circuit. The unit fan is then turned off by the P/E switch with pneumatic controls or electric contactor with electronic controls. CAUTION: For electronically controlled unit, a minimum CFM value other than zero may cause the damper to drive open when the central system is off. www.carnes.com B-93

UNIT SELECTION PROCEDURE Standard Fan Terminal Units QUICK SELECTION TABLE CONSTANT VOLUME FAN TERMINALS WITH PSC MOTORS (Standard Design) Minimum Minimum Maximum Full Load Full Load Maximum Primary Primary Fan Unit Fan Inlet Motor Amps Amps Primary Air Flow Air Flow CFM Type Size Size (In.) HP 120 V 277V Air Flow (Pneumatic) (Electronic) 0.25 wg B 5 1/6 2.0 1.0 350 0 or 75 0 or 45 550 B 6 1/6 2.0 1.0 500 0 or 110 0 or 65 550 C 7 1/6 2.9 1.0 700 0 or 140 0 or 85 750 AC_J D 8 1/4 5.0 1.5 1000 0 or 185 0 or 105 1275 E 10 1/2 7.2 3.6 1500 0 or 300 0 or 155 1780 F 12 3/4 11.4 4.7 2300 0 or 430 0 or 225 2430 G 14 1 6.5 3100 0 or 600 0 or 335 3100 G 16 1 6.5 4200 0 or 780 0 or 465 3100 J 16 (2) 3/4 19.5 7.8 4200 0 or 780 0 or 465 4130 CONSTANT VOLUME FAN TERMINALS WITH ECM MOTORS (Standard Design) Minimum Minimum Maximum Full Load Full Load Maximum Primary Primary Fan Unit Fan Inlet Motor Amps Amps Primary Air Flow Air Flow CFM Type Size Size (In.) HP 120 V 277V Air Flow (Pneumatic) (Electronic) 0.25 wg B 6 1/3 2.2 0.9 500 0 or 110 0 or 65 550 C 7 1/3 2.9 1.3 700 0 or 140 0 or 85 800 D 8 1/3 3.8 1.8 1000 0 or 185 0 or 105 1200 AC_J E 10 1 5.2 2.3 1500 0 or 300 0 or 155 1800 F 12 1 10.4 4.7 2300 0 or 430 0 or 225 2500 H 14 (2) 1 8.8 3.7 3100 0 or 600 0 or 335 3200 J 16 (2) 1 16.6 7.0 4200 0 or 780 0 or 465 4200 NOTES: AC Units = Constant Volume Terminals (Series) www.carnes.com B-95

FAN TERMINAL UNITS Constant Volume (Series Flow), Standard Design Models ACF w/o Coil ACW w/hot Water Coil ACE w/electric Coil The Carnes constant volume fan terminal unit provides constant air volume to the space while retaining the advantages of a variable air volume system. The primary air control assembly operates in the same manner as a standard throttling control valve when cooling loads are high. As cooling loads diminish the integral blower(s) induces warm ceiling plenum air to maintain constant air volume. Features Include: Air flow capacities to 4130 CFM. Durable 22 gauge galvanized steel casing construction. Bottom access panel for internal components. Flange or slip and drive discharge connections. Forward curved centrifugal type fan assemblies with thermally protected, Permanent Split Capacitor or ECM type, fractional horsepower motors. Multiple voltages available. Adjustable SCR fan speed control. Fan/motor assemblies are isolated from the casing using rubber isolators to minimize vibration transmission. Low leakage primary air damper design. Secondary air filter rack. Performance data based on tests conducted in accordance with AHRI Standard 880-2008. Air flow switch. All units are equipped with pressure independent pneumatic or electronic controls. Field adjustable P/E switch with pneumatic controls. Tri-Averaging type velocity sensor and calibration chart for measuring air flow through the primary air damper. Insulation is 1 thick, 1-1/2 lb. dual density fiberglass with surface treated to prevent air erosion, UL listed and meets NFPA 90A requirements. Damper controls and fan controls are located in one enclosure. AHRI listed. Optional ETL listing. Optional secondary air sound baffle. Sound baffle is factory attached to secondary air inlet. Optional one to four row hot water coils (Model ACW). Coil is factory attached to the unit discharge. Optional one or two stage electric reheat coils (Model ACE). Coil is factory attached to unit discharge. Optional secondary air filters, Class I (re-usable) or Class II (throw away). Optional non-fused or fused fan disconnect switch. Optional foil coated insulation. Optional fiber-free liner. Optional dual wall. Available Modules: Basic control unit Model ACF. Basic control unit with hot water coil Model ACW. Basic control unit with electric coil Model ACE. IAQ IAQ Insulation Available B-122 www.carnes.com

GENERAL INFORMATION ECM Motors Fan powered constant volume terminal units are designed to deliver a constant volume of air to a given space. Currently a PSC motor with an SCR is used to turn a blower wheel at a constant rate. As primary air from the air handler is increased the amount of air induced from the conditioned space is decreased. Because there are multiple variable air volume units in a system, the duct static pressure may increase or decrease depending on the total load. As the static pressure in the duct system changes the typical PSC motor blower combination can not adjust itself and therefore the CFM delivered to an area will vary. This makes initial balancing difficult and provides a less than ideal flow of air to the conditioned space. The ideal speed at which an induction motor can turn is fixed by the frequency of the voltage applied and the number of poles it contains. The motor s speed can be reduced by altering the voltage applied across its windings. This can be done with resistors, inductors, transformers or solid state speed controls. Decreasing the voltage reduces the starting and full-load torque, increases the rotors slip and decreases the motors efficiency. The further the motor operates from its ideal speed, the greater the energy loss and running temperature of the motor. The lack of torque control prevents precise air flow control and the low frequency noise may increase. In response to the need for a high efficiency motor in which speed can be set and maintained, GE developed an Electronically Commutated Motor or ECM. It is an ultra high efficiency brushless DC motor with a built in inverter. The electronics package, included with the GE ECM motor serves two purposes. One, it switches the DC magnetic fields which allow the motor to operate. Two, it controls torque and speed so that the air flow is maintained despite the pressure seen by the fan. The ECM can be programmed in the factory to set maximum and minimum values which can then be adjusted in the field to the desired CFM. Once set, the motor will maintain constant air flow within + or 5%. In 1974 the first fan powered variable air volume boxes were introduced to the market. They provided significant energy savings compared to standard systems at that time because of their ability to recapture plenum heat. With increasing energy costs, the demand for higher efficiency motors has increased. Through testing, the Carnes company has shown that the ECM has proven true to its reputation for using less energy. The following chart shows the wattage used at various air flows over the range of units provided by Carnes. ECM Front of VCU www.carnes.com B-99

GENERAL INFORMATION ECM Motors Energy Savings The energy savings for the ECM motor can be quite significant. Depending on energy cost for a given area, the payback for the ECM motor can be seen in as little as two years. One of the unique features of the ECM motor is that it can be controlled by a 0-10V dc signal from the building automation system. The fan speed can now be increased in cooling mode and decreased for heating mode. This allows the design engineer to further optimize performance. ECM Motor Control ECM Motor Taps The ECM motor was originally designed for the residential HVAC market. Because of the need to provide a different air flow rate for heating versus cooling, two different tap positions were provided. In addition two more tap wires are provided. One is to adjust the flow rate, for example in an application where humidity control was a concern. The other provided a way to delay the start of the fan according to a desired delay profile. The ECM motor tap connections are provided via the ECM control connection. Additional taps are provided as a way for the thermostat to send a control signal to the ECM motor. All of these tap positions are available when the ECM motor is programmed for the TSTAT mode. (See figure 1, table 1) Variable Speed Control When applying the ECM to use with a Variable air volume box it is more desirable to be able to provide a variable speed control. This allows the ECM to operate over a range of CFM values. The maximum and minimum air flow rates are programmed into the motor at the factory. The speed of the motor is then set by Pulse width modulated (PWM) signal sent to the ECM motor via a special controller provided by Carnes. The ECM tap positions are all given below. The positions used by Carnes for the Variable air volume application are out lined in blue. B-100 www.carnes.com

GENERAL INFORMATION ECM Motors Table 1 PIN DESCRIPTION 1 C1 2 W/W1 3 C2 (GREEN WIRE) COMMON 4 DELAY 5 COOL 6 Y1 7 ADJUST 8 OUT (GREEN WIRE) 9 O PK/PWM (RED) CONTROLS 10 SPEED OF MOTOR 11 HEAT 12 R 13 EM/W2 14 Y/Y2 G (WHITE WIRE) MOTOR 15 ON/OFF GROUND 16 OUT+ (BLACK) - TACHOMETER Figure 1 The GE ECM motor is unique in that it is turned off and on via a 24 V control signal. Power should not be disrupted to the motor as a means to control the motor. In fact doing so will reduce the life span of the motor. Carnes Control Options Carnes is working together with Evolution Controls to provide three control options with the ECM motor. The standard electronic control is the VCU. It has a digital number readout which allows the user to see the RPM output of the motor as well as the flow index. The flow index is a range of flow from 0-100. A flow index of zero marks the minimum flow of the VAV box. A flow index of 100 is the maximum air flow of the VAV box. Refer to table 2 which is a listing of the expected CFM (within + or 10%) for the various size units. Once a flow rate is set on the VAV unit, the ECM will maintain the air flow within + or 5% of the set value. www.carnes.com B-101

GENERAL INFORMATION ECM Flow Index J-Series ECM Motor Flow Index Table AC_J06 AC_J07 AC_J08 AC_J10 AC_J12 AC_J14 AC_J16 Min. CFM 200 450 700 1100 1800 2200 3100 Max. CFM 550 800 1200 1800 2500 3200 4200 Flow Index Fan CFM Fan CFM Fan CFM Fan CFM Fan CFM Fan CFM Fan CFM 1 200 450 700 1100 1800 2200 3100 2 204 454 705 1107 1807 2210 3111 3 207 457 710 114 1814 2220 3122 4 211 461 715 1121 1821 2230 3133 5 214 464 720 1128 1828 2240 3144 6 218 468 725 1135 1835 2251 3156 7 221 471 730 1142 1842 2261 3167 8 225 475 735 1149 1849 2271 3178 9 228 478 740 1157 1857 2281 3189 10 232 482 745 1164 1864 2291 3200 11 235 485 751 1171 1871 2301 3211 12 239 489 756 1178 1878 2311 3222 13 242 492 761 1185 1885 2321 3233 14 246 496 766 1192 1892 2331 3244 15 249 499 771 1199 1899 2341 3256 16 253 503 776 1206 1906 2352 3267 17 257 507 781 1213 1913 2362 3278 18 260 510 786 1220 1920 2372 3289 19 264 514 791 1227 1927 2382 3300 20 267 517 796 1234 1934 2392 3311 21 271 521 801 1241 1941 2402 3322 22 274 524 806 1248 1948 2412 3333 23 278 528 811 1256 1956 2422 3344 24 281 531 816 1263 1963 2432 3356 25 285 535 821 1270 1970 2442 3367 26 288 538 826 1277 1977 2453 3378 27 292 542 831 1284 1984 2463 3389 28 295 545 836 1291 1991 2473 3400 29 299 549 841 1298 1998 2483 3411 30 303 553 846 1305 2005 2493 3422 31 306 556 852 1312 2012 2503 3433 32 310 560 857 1319 2019 2513 3444 33 313 563 862 1326 2026 2523 3456 34 317 567 867 1333 2033 2533 3467 35 320 570 872 1340 2040 2543 3478 36 324 574 877 1347 2047 2554 3489 37 327 577 882 1355 2055 2564 3500 38 331 581 887 1362 2062 2574 3511 39 334 584 892 1369 2069 2584 3522 40 338 588 897 1376 2076 2594 3533 41 341 591 902 1383 2083 2604 3544 42 345 595 907 1390 2090 2614 3556 43 348 598 912 1397 2097 2624 3567 44 352 602 917 1404 2104 2634 3578 45 356 606 922 1411 2111 2644 3589 46 359 609 927 1418 2118 2655 3600 47 363 613 932 1425 2125 2665 3611 48 366 616 937 1432 2132 2675 3622 B-102 www.carnes.com

GENERAL INFORMATION ECM Flow Index J-Series ECM Motor Flow Index Table 49 370 620 942 1439 2139 2685 3633 50 373 623 947 1446 2146 2695 3644 51 377 627 953 1454 2154 2705 3656 52 380 630 958 1461 2161 2715 3667 53 384 634 963 1468 2168 2725 3678 54 387 637 968 1475 2175 2735 3689 55 391 641 973 1482 2182 2745 3700 56 394 644 978 1489 2189 2756 3711 57 398 648 983 1496 2196 2766 3722 58 402 652 988 1503 2203 2776 3733 59 405 655 993 1510 2210 2786 3744 60 409 659 998 1517 2217 2796 3756 61 412 662 1003 1524 2224 2806 3767 62 416 666 1008 1531 2231 2816 3778 63 419 669 1013 1538 2238 2826 3789 64 423 673 1018 1545 2245 2836 3800 65 426 676 1023 1553 2253 2846 3811 66 430 680 1028 1560 2260 2857 3822 67 433 683 1033 1567 2267 2867 3833 68 437 687 1038 1574 2274 2877 3844 69 440 690 1043 1581 2281 2887 3856 70 444 694 1048 1588 2288 2897 3867 71 447 697 1054 1595 2295 2907 3878 72 451 701 1059 1602 2302 2917 3889 73 455 705 1064 1609 2309 2927 3900 74 458 708 1069 1616 2316 2937 3911 75 462 712 1074 1623 2323 2947 3922 76 465 715 1079 1630 2330 2958 3933 77 469 719 1084 1637 2337 2968 3944 78 472 722 1089 1644 2344 2978 3956 79 476 726 1094 1652 2352 2988 3967 80 479 729 1099 1659 2359 2998 3978 81 483 733 1104 1666 2366 3008 3989 82 486 736 1109 1673 2373 3018 4000 83 490 740 1114 1680 2380 3028 4011 84 493 743 1119 1687 2387 3038 4022 85 497 747 1124 1694 2394 3048 4033 86 501 751 1129 1701 2401 3059 4044 87 504 754 1134 1708 2408 3069 4056 88 508 758 1139 1715 2415 3079 4067 89 511 761 1144 1722 2422 3089 4078 90 515 765 1149 1729 2429 3099 4089 91 518 768 1155 1736 2436 3109 4100 92 522 772 1160 1743 2443 3119 4111 93 525 775 1165 1751 2451 3129 4122 94 529 779 1170 1758 2458 3139 4133 95 532 782 1175 1765 2465 3149 4144 96 536 786 1180 1772 2472 3160 4156 97 539 789 1185 1779 2479 3170 4167 98 543 793 1190 1786 2486 3180 4178 99 546 796 1195 1793 2493 3190 4189 100 550 800 1200 1800 2500 3200 4200 www.carnes.com B-103

GENERAL INFORMATION ECM Motors Visual Control Unit (VCU) The EVO/ECM-VCU control allows accurate manual adjustment and monitor of fans using General Electric s ECM Motor. (See Figure 2) The EVO/ECM-VCU features a 4 digit LED numerical display to allow easy reading in dark spaces. Watch the display and set the flow index with a screwdriver to adjust. Twenty seconds later, the display shows the motor RPM. Then, the display periodically alternates between the flow index and motor RPM. The EVO/ECM-VCU may also be used where automation systems only turn the fan on or off. Figure 2 Front of VCU Back of VCU control unit Specifications: Power NEC Class II Only 24 Vac ± 20% 50/60 Hz 4 W, 6 VA Flow Index Adjustment 270 rotation F Off-0-100 RPM 0-2000 RPM ± 2% Outputs Go & Vspd ECM 2.3 Stability Operating Connections 24 Vdc @ 20 ma Set for Vspd Operation Set Status Flag (7) to RPM Thermal >0.01 %/ F 0 F to 130 F (-18 C to 55 C) Environment 10-80% rh 1/4 Tabs B-104 www.carnes.com

GENERAL INFORMATION ECM Motors Automatic Control Unit (ACU+) If digital controls are being used on the project it is possible to control the speed of the ECM motor with a 0-10V control signal using the EVO ACU+ unit. (See figure 3) The on/off signal is provided at a 24V input. Another option is to turn the motor on/off with a 0-1V signal and to use the 2-10V for speed control. The EVO/ECM-ACU+ allows remote adjustment of the output from 0% to 100% of the programmed control range. A LED on the control continuously flashes out the flow index (percent of the programmed control range), so instruments are not required to read the value. The "P" version provides ON/OFF control by switching the motor's "GO" control when the input signal drops below the 2 volt (4 ma) operating point. Figure 3 The green LED continuously indicates the flow index. After a pause, the LED flashes out the tens digit, then the units digit of a number (percent) between 1 and 99. Two extra long flashes indicate a flow index of 0%. Long flashes represent the tens digit, and short flashes represent the units digit. A flow index of 23%, flashes two longs and three shorts. www.carnes.com B-105